Virtualization in adaptive stream creation and delivery

ABSTRACT

An adaptive streaming server, a method, and a system are described herein that create a content stream to be delivered to one or more clients by segmenting the content into data structures which are stored in random access memory (volatile storage) rather than segmenting the content into segment files which are stored on a disk or database (non-volatile storage).

CLAIM OF PRIORITY

This application is a continuation application of U.S. patentapplication Ser. No. 13/329,443, filed Dec. 19, 2011, now pending. Thecontents of this document are hereby incorporated by reference herein.

TECHNICAL FIELD

The present invention relates to a streaming server, a method, and asystem that creates a content stream to be delivered to one or moreclients by segmenting the content into data structures which are storedin random access memory (volatile storage) rather than segmenting thecontent into segment files which are stored on a disk or database(non-volatile storage).

BACKGROUND

The following abbreviations and terms are herewith defined, at leastsome of which are referred to within the following description about atleast the prior art and/or the present invention.

-   CDN Content Distribution Network-   HLS HTTP Live Streaming-   HTTP Hypertext Transfer Protocol-   IP Internet Protocol-   MPEG Moving Picture Experts Group-   MRTG Multi Router Traffic Grapher-   RTP Real Time Transport Protocol-   RTSP Real Time Streaming Protocol-   SNMP Simple Network Management Protocol-   Volatile Storage (volatile memory): is computer memory that requires    power to maintain the stored information, unlike non-volatile memory    which does not require a maintained power supply. Most forms of    modern random access memory (RAM) are volatile storage, including    dynamic random access memory (DRAM) and static random access memory    (SRAM). Content addressable memory and dual-ported RAM are usually    implemented using volatile storage.-   Non-Volatile Storage (Non-volatile memory): is computer memory that    can retain the stored information even when not powered. Examples of    non-volatile memory include read-only memory, flash memory,    ferroelectric RAM, most types of magnetic computer storage devices    (e.g. hard disks, floppy disks, and magnetic tape), optical discs,    and early computer storage methods such as paper tape and punched    cards.

Adaptive bitrate streaming is a technique used by an adaptive streamingserver for streaming multimedia over one or more networks to userdevices (e.g., computers, mobile communication devices, tablets, smartphones). While in the past most video streaming technologies utilizedstreaming protocols such RTP with RTSP, today's adaptive streamingtechnologies are mostly based on HTTP and are designed to workefficiently over large distributed HTTP networks such as the Internet.

HTTP adaptive bit rate streaming requires that the adaptive streamingserver have multiple files of the content stream (source video,multimedia) which are encoded at different bit rates. The adaptivestreaming server then switches between streaming the different encodingsof the content file based on requests received from the user's device.The result of the HTTP stream is that the user's device experiences verylittle buffering and a fast start time so the user has a good experiencefor both high-end and low-end network connections. Today, there areseveral HTTP adaptive bit rate streaming technologies that can be usedby an adaptive streaming server for streaming multimedia over networkssuch as the Internet to user devices. For example, Apple's HTTP LiveStream (HLS) m3u8 file system is one such HTTP adaptive bit ratestreaming technology where a “manifest” file is created to referencemany video segments which are updated in real time to play in aparticular order. Other HTTP adaptive bit rate streaming technologiesinclude Adobe's Dynamic stream for Flash, Microsoft's Smooth Streamingetc. . . .

Referring to FIGS. 1A-1D (PRIOR ART), there several diagrams used tohelp explain how a traditional system 100 can implement a HTTP adaptivebit rate streaming technology. As shown in FIG. 1A (PRIOR ART), thetraditional system 100 includes a content provider 102 (e.g., abroadcast network 102 a, CDN/content store 102 b), an adaptive streamingencoder/transcoder 104, an adaptive streaming server 106, a network 107(e.g., IP network 107, CDN network 107), and clients 108. The adaptivestreaming server 106 receives a request from a particular client 108 afor a source video 110 and then retrieves the source video 110 from thecontent provider 102 (step 1). In this example, the broadcast network102 a has the requested source video 110 and provides the source video110 to the adaptive streaming encoder/transcoder 104. The adaptivestreaming encoder/transcoder 104 takes the source video 110 andgenerates multiple files 112 a, 112 b, 112 c and 112 d (for example) ofthe same video and audio content but which are encoded at different bitrates. For example, the adaptive streaming encoder/transcoder 104 canoutput a 4M bit rate file 112 a, a 2M bit rate file 112 b, a 1M bit ratefile 112 c and a 512K bit rate file 112 d which are all key framedaligned with one another by PTSs/DTSs 114 (see FIG. 1B (PRIOR ART)).Thus, the 4M bit rate file 112 a has a section 116 a which contains thesame video and audio content as the corresponding sections 116 b, 116 cand 116 d of the 2M bit rate file 112 b, the 1M bit rate file 112 c andthe 512K bit rate file 112 d. However, the 4M bit rate file's section116 a has a higher quality than the 2M bit rate file's section 116 bwhich has a higher quality than the 1M bit rate file's section 116 cwhich in turn has a higher quality than the 512K bit rate file's section116 d.

The adaptive streaming server 106 includes a multicast packet escrow 118which receives the multiple files 112 a, 112 b, 112 c and 112 d and apacket escrow database 120 (non-volatile storage) which stores themultiple files 112 a, 112 b, 112 c and 112 d. The adaptive streamingserver 106 includes a segmenting unit 122 which functions to segmenteach of the stored files 112 a, 122 b, 112 c, and 112 d into multiplesegment files 120 a _(1-n), 120 b _(1-n), 120 c _(1-n), and 120 d _(1-n)(see FIG. 1C (PRIOR ART)). The adaptive streaming server 106 includes asegment database 124 (non-volatile storage) which stores the segmentfiles 120 a _(1-n), 120 b _(1-n), 120 c _(1-n), and 120 d _(1-n). Eachsegment file 120 a _(1-n), 120 b _(1-n), 120 c _(1-n), and 120 d _(1-n)contains video and audio packets for a predetermined time duration(e.g., 10 seconds). In this example, the segment files 120 a ₁, 120 b ₁,120 c ₁, and 120 d ₁ (for example) would be associated with time codest1-t2 and segment files 120 a ₄, 120 b ₄, 120 c ₄, and 120 d ₄ (forexample) would be associated with time codes t4-t5.

The adaptive streaming server 106 has a HTTP server 126 which interfaceswith the segment database 124 and creates a master manifest file 128which includes child manifest files 130 a, 130 b, 130 c and 130 d (forexample)(see FIG. 1D (PRIOR ART)). Each child manifest file 130 a, 130b, 130 c and 130 d respectively includes references 132 a _(1-n), 132 b_(1-n), 132 c _(1-n), and 132 d _(1-n) to each of the segment files 120a _(1-n), 120 b _(1-n), 120 c _(1-n), and 120 d _(1-n). The HTTP server126 sends the master manifest file 128 through the network 107 to client108 a (step 2). Thereafter, the client 108 a sends a request includingone of the child manifest file's reference 132 a ₁ (for example) throughthe network 107 to the HTTP server 126 (step 3). The HTTP server 126uses the requested reference 132 a, to retrieve and send thecorresponding segment file 120 a, through the network 107 to the client108 a which plays the segment file 120 a, (step 4). The client 108 asends another request identifying one of the child manifest file'sreference 132 b ₂ (for example) through the network 107 to the HTTPserver 126 (step 3′). The HTTP server 126 uses the requested references132 b ₂ to retrieve and send the corresponding segment file 120 b ₂through the network 107 to the client 108 a which playbacks the segmentfile 120 b ₂ (step 4′). The client 108 a continues to send requests forspecific segment files 120 a _(3-n), 120 b _(3-n), 120 c _(3-n), and 120d _(3-n) (for example) and the HTTP server 126 sends the requestedsegment files 120 a _(3-n), 120 b _(3-n), 120 c _(3-n), and 120 d_(3-n), back to the client 108 a which playbacks the received segmentfiles 120 a _(3-n), 120 b _(3-n), 120 c _(3-n), and 120 d _(3-n) (steps3“and 4”). In this way, the client 108 a is able to playback therequested source video 110 while experiencing very little buffering anda fast start time so the user has a good experience for both high-endand low-end network connections.

In effect, the traditional adaptive streaming server 106 can accept liveand on demand content streams. These content streams are divided intomanageable segments of different qualities and written into files whichare stored on a disk (shown as segment database 124). The clients 108can then retrieve these files for video display by making HTTP queriesto a primitive web server. However, there are several problems with thecurrent solution:

-   -   Flexibility in dividing (chopping up) a segment file 120 a        _(1-n), 120 b _(1-n), 120 c _(1-n), and 120 d _(1-n), is        limited. Thus, extracting a subset of a segment becomes rather        difficult.    -   The traditional adaptive server 106 requires redundant copies of        VOD streams as the server 106 tries to store the original        content file and all of its additional segment files 120 a        _(1-n), 120 b _(1-n), 120 c _(1-n), and 120 d _(1-n).

Accordingly, there is a need to address these problems and otherproblems associated with the traditional adaptive server 106. This needand other needs are satisfied by the present invention.

SUMMARY

A streaming server, a method, and a system that address theaforementioned problems and other problems are described in theindependent claims of the present application. Advantageous embodimentsof the streaming server, the method, and the system have been describedin the dependent claims of the present application.

In one aspect, the present invention provides a streaming server forproviding a content stream through a network to a client. The streamingserver comprises a server, a segmenting unit, and a random access memoryunit. The server has an input interface configured to receive a requestfrom the client to play the content stream. The segmenting unit isconfigured to receive the content stream and segment the content streaminto a plurality of data structures, where the plurality of datastructures encompass pointers which correspond to time codes and areference to the unsegmented content stream. The random access memoryunit is configured to store the plurality of data structures and thepointers. The server further comprises: (a) a processing unit configuredto generate a manifest that includes a plurality referencescorresponding to a plurality of fragments of the content stream; (b) anoutput interface configured to send the manifest to the client; (c) theinput interface is configured to receive a request from the client tofetch one of the fragments corresponding to the content stream; (d) theprocessing unit is configured to obtain bytes associated with therequested fragment from the data structures stored in the random accessmemory unit, where the processing unit uses a start time and a stop timeassociated with the requested fragment and computes the correspondingpointers associated with the plurality of data structures to look upbytes from the one or more data structures associated with the requestedfragment; and (e) the output interface is configured to send the bytesassociated with the requested fragment to the client. An advantage ofthe streaming server is that segmentation can be deferred until itbecomes necessary to play the content stream.

In yet another aspect, the present invention provides a methodimplemented by a streaming server for providing a content stream througha network to a client. The method comprises the steps of: (a) receivinga request from the client to play the content stream; (b) receiving thecontent stream; (c) segmenting the content stream into a plurality ofdata structures, wherein the plurality of data structures encompasspointers which correspond to time codes and a reference to theunsegmented content stream; (d) storing the plurality of data structuresand the pointers in a random access memory unit; (e) generating amanifest that includes a plurality references corresponding to aplurality of fragments of the content stream; (f) sending the manifestto the client; (g) receiving a request from the client to fetch one ofthe fragments corresponding to the content stream; (h) obtaining bytesassociated with the requested fragment from the data structures storedin the random access memory unit by using a start time and a stop timeassociated with the requested fragment and computes the correspondingpointers associated with the plurality of data structures to look upbytes from the one or more data structures associated with the requestedfragment; and (i) sending the bytes associated with the requestedfragment to the client. An advantage of the method is that segmentationcan be deferred until it becomes necessary to play the content stream.

In still yet another aspect, the present invention provides a system forproviding a content stream to through a network to a client. The systemcomprises a content provider and a streaming server which interfaceswith the client through the network. The streaming server is configuredto: (a) receive a request from the client to play the content stream;(b) receive the content stream from the content provider; (c) segmentthe content stream into a plurality of data structures, where theplurality of data structures encompass pointers which correspond to timecodes and a reference to the unsegmented content stream; (d) generate amanifest that includes a plurality references corresponding to aplurality of fragments of the content stream; (e) send the manifest tothe client; (f) receive a request from the client to fetch one of thefragments corresponding to the content stream; (g) obtain bytesassociated with the requested fragment from the data structures storedin the random access memory unit by using a start time and a stop timeassociated with the requested fragment and the pointers associated withthe plurality of data structures to look up bytes from the one or moredata structures associated with the requested fragment; and (h) send thebytes associated with the requested fragment to the client. An advantageof the streaming server is that segmentation can be deferred until itbecomes necessary to play the content stream.

Additional aspects of the invention will be set forth, in part, in thedetailed description, figures and any claims which follow, and in partwill be derived from the detailed description, or can be learned bypractice of the invention. It is to be understood that both theforegoing general description and the following detailed description areexemplary and explanatory only and are not restrictive of the inventionas disclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete understanding of the present invention may be obtainedby reference to the following detailed description when taken inconjunction with the accompanying drawings:

FIGS. 1A-1D (PRIOR ART) are several diagrams used to help explain how atraditional system can provide a content stream through a network to aclient;

FIG. 2 is a diagram of an exemplary system configured to provide acontent stream through a network to a client in accordance with anembodiment of the present invention;

FIG. 3 is a flowchart illustrating the steps of an exemplary methodimplemented by an adaptive streaming server to provide a content streamthrough a network to a client in accordance with an embodiment of thepresent invention;

FIG. 4 is a diagram used to help explain one way that an adaptivestreaming server can segment the content stream into data structures(virtual files) in accordance with an embodiment of the presentinvention;

FIGS. 5A-5B are diagrams used to help explain one way that an adaptivestreaming server can segment the video to place into the data structuresplus how it can scan on further into the content stream to ensure thecorresponding audio packets are also contained in the correct datastructures so that both audio and video time stamps match up in thecontent stream in accordance with an embodiment of the presentinvention;

FIG. 6 is a diagram of an exemplary system including an adaptivestreaming server configured to receive a live content stream and thenadaptively deliver the live content stream via an IP network to one ormore clients in accordance with an embodiment of the present invention;and

FIG. 7 is a diagram of an exemplary system including an adaptivestreaming server configured to receive a on-demand content stream andthen adaptively deliver the on-demand content stream via an IP networkto one or more clients in accordance with an another embodiment of thepresent invention.

DETAILED DESCRIPTION

Referring to FIG. 2, there is a diagram of an exemplary system 200configured to provide a content stream 203 through a network 208 to aclient 202 in accordance with an embodiment of the present invention.The system 200 includes a content provider 204 and a streaming server206. The content provider 204 interfaces with the streaming server 206which in turn interfaces with the client 202 (only one shown) throughthe network 208 (e.g., IP network 208, CDN network 208, wireless network208 or any combination thereof). Alternatively, the content provider 204may be connected to the streaming server 206 through the network 208.The streaming server 206 includes a segmenting unit 210, a random accessmemory 211 (volatile storage 211), and a server 212 (e.g., HTTP server212).

The server 212 further includes an input interface 216, a processingunit 218, and an output interface 220. In this example, the processingunit 218 includes a processor 218 a which executes process-executableinstructions stored in a memory 218 a (e.g., non-volatile memory 218 a)to enable the operations described below. The input interface 216 isconfigured to receive a request from the client 202 to play the contentstream 203 (step 1). The segmenting unit 210 is configured to receiveone file of the content stream 203 or multiple files of the contentstream 203 where the multiple files are encoded at different bit rates(step 2). For example, the content provider 204 (e.g., CDN content store204) may provide the file or multiple files of the content stream 203(see FIG. 7). Or, the content provider 204 (e.g., broadcast network 204a) may provide a single file of the content stream 203 to an adaptivestreaming friendly encoder/transcoder which then generates the file ormultiple files of the content stream 203 and provides the file ormultiple files to the segmenting unit 210 (see FIG. 6).

The segmenting unit 210 is further configured to segment the file oreach of the multiple files into a plurality of data structures (notsegment files) which encompass pointers which correspond to time codesand a reference to the unsegmented content stream (step 3). The randomaccess memory 211 (volatile memory) is configured to store the datastructures of the file or the multiple files of the content stream 203(step 4). The processing unit 218 is configured to generate a manifestif there is one file of the content stream 203 or a master manifest ifthere are multiple files of the content stream 203 (step 5). Themanifest or master manifest would be stored in the random access memoryunit 211. In one example, the manifest includes references (e.g., URLs)corresponding to fragments (e.g., 10 second fragments) of the contentstream 203. In another example, the master manifest includes multiplechild manifests (e.g., child manifest) (step 5). For instance, the firstchild manifest has references (e.g., URLs) corresponding to fragments(e.g., 10 second fragments) having a first bit rate of the contentstream 203, the second child manifest has references (e.g., URLs)corresponding to fragments (e.g., 10 second fragments) having a secondbit rate of the content stream 203 etc. . . . where the first bit rateis higher than the second bit rate etc. . . . The output interface 220is configured to send the manifest or master manifest to the client 202(step 6). The input interface 216 is configured to receive a requestfrom the client 202 to fetch a specific one of the fragmentscorresponding to the content stream 203 (step 7). The processing unit218 is configured to obtain bytes associated with the requested fragmentfrom the data structures stored in the random access memory unit 111.For example, the processing unit 218 uses a start time and a stop timeassociated with the requested fragment and computes the correspondingpointers associated with the data structures to lookup bytes from theone or more data structures associated with the requested fragment (step8). The processing unit 218 when looking-up the bytes from the one ormore data structures associated with the requested fragment can beconfigured to perform an interpolation if need to obtain the bytes ofthe requested fragment. The output interface 220 is configured to sendthe requested fragment to the client 202 (step 9). Thereafter, steps 7-9would be repeated so the client 202 can obtain and playback the contentstream 203.

Referring to FIG. 3, there is a flowchart illustrating the steps of anexemplary method 300 implemented by the streaming server 206 to providethe content stream 203 through the network 208 to the client 202 inaccordance with an embodiment of the present invention. At step 302, thestreaming server 206 receives a request from the client 202 to play thecontent stream 203. At step 304, the streaming server 206 receives onefile or multiple files of the content stream 203 where the multiplefiles are encoded at different bit rates. At step 306, the streamingserver 206 segments the file or each of the multiple files into aplurality of data structures (not segment files) which encompasspointers which correspond to time codes and a reference to theunsegmented content stream. At step 308, the streaming server 206 storesthe data structures in the random access memory 211. At step 310, thestreaming server 206 generates a manifest (if one file of the contentstream 203 is used) or a master manifest (if multiple files withdifferent encoding rates of the content stream 203 are used). At step312, the streaming server 206 sends the manifest or master manifest tothe client 202. At step 314, the streaming server 206 receives a requestfrom the client 203 to fetch a specific one of the fragmentscorresponding to the content stream 203. At step 316, the streamingserver 206 obtains bytes associated with the requested fragment from thedata structures stored in the random access memory unit 111. Forexample, the streaming server 206 uses a start time and a stop timeassociated with the requested fragment and computes the correspondingpointers associated with the plurality of data structures to lookupbytes from the one or more data structures associated with the requestedfragment. The streaming server 206 when looking-up the bytes from theone or more data structures associated with the requested fragment canbe configured to perform an interpolation if need to obtain the bytes ofthe requested fragment. At step 318, the streaming server 206 sends therequested fragment to the client 202. Thereafter, steps 314, 316 and 318would be repeated so the client 202 can obtain and playback the contentstream 203.

Hence, the streaming server 206 in accordance with an embodiment of thepresent invention addresses the aforementioned problems of the prior artby implementing the following:

1. VOD and Multi-Program Live Transport Streams both should only beparsed for Single-Program Adaptive Transport Streaming when they areneeded by a client. Then, the streaming server 206 in creating anadaptive stream need only require that the content be broken up intodata structures which are stored in random access memory 211 (volatilestorage) rather than breaking up the content into locally segmentedfiles stored on disk (non-volatile storage). These data structures willbe available for clients 202 to retrieve as a file stream.

2. While parsing a stream, the streaming server 206 creates a manifestor master manifest that contains a set of virtual pointers to the datastructures which the stream is broken out into. This allows a client 202to play the content stream 203 in the same manner it would with anytraditional adaptive streaming system but the content stream 203 will beavailable much faster due to the data structures and the client 202 doesnot need to have knowledge about the storage format and management ofthe content's data in the streaming server 206.

A set of data for an exemplary data structure is as follows:

public class SimplePacketSpan extends AbstractPacketSpan {private finallong s0; // segment start time private final long e0; // segment endtime OneFileStore enclosing; // packet database } public classOneFileStore {private long end; // packet database end time private longstart; // packet database start time protected TransportPacketBag bag;//reference to packets stored on disk protected PCRSlope slope; //“object” (algorithm+data) allows one to map from a time to thecorresponding packets on disk. An exemplary implementation uses linearinterpolation }

A detailed discussion about several exemplary ways that the streamingserver 206 can implement the aforementioned method 300 is provided belowwith respect to FIGS. 4-6.

Referring to FIG. 4, there is a diagram which shows one way how thestreaming server 206 (e.g., adaptive streaming server 206) can segmentthe content stream 203 into data structures 402, 404 and 406 (virtualfiles) in accordance with an embodiment of the present invention. Inparticular, this diagram shows the following:

-   -   1. A snapshot of the random access memory 211 denoting the data        structures 402, 404 and 406 that make up the different qualities        of the content stream 203 which the adaptive streaming server        206 has segmented.    -   2. Each letter number combination (P1, P2 . . . P15, Q1, Q2 . .        . Q15, N1, N2 . . . N15) references a specific pointer 412 to a        segment boundary in the content stream 203    -   3. The adaptive streaming server 206 can use the linear guide        data feed to segment (chop) the content stream 206 to obtain the        subset of data structures 402, 404 and 406 that reference a        program.

Referring to FIGS. 5A-5B, there are diagrams which show on way how thestreaming server 206 (e.g., adaptive streaming server 206) can segmentthe video to place into the data structures 402, 404 and 406 (seealphanumeric A) plus how it can scan on further into the content stream203 to ensure the corresponding audio packets are also contained in thecorrect data structures 402, 404 and 406 so that both audio and videotime stamps match up in the content stream 203 (see alphanumeric B).This provides the flexibility to cut new virtual segments and subsetsanywhere in the content stream 203 in a fraction of the time whencompared to the state of the art as the content stream 203 is beingdelivered to a client 202. For example, one can use the adaptivestreaming server 206 to combine parts of any two different encoded videofiles if desired such as combining an advertisement into the contentstream. In addition, the diagrams show how the adaptive streaming server206 can generate a master manifest 502 (see alphanumeric C). The mastermanifest includes multiple child manifests 504 a, 504 b . . . 504 n(e.g., child manifests 504 a, 504 b . . . 504 n). For example, the firstchild manifest 504 a has multiple references 506 a (e.g., URLs)corresponding to fragments (e.g., 10 second fragments) having a firstbit rate of the content stream 203. The second child manifest 504 b hasreferences 506 b (e.g., URLs) corresponding to fragments (e.g., 10second fragments) having a second bit rate of the content stream 203.The nth child manifest 504 n has references 506 n (e.g., URLs)corresponding to fragments (e.g., 10 second fragments) having a nth bitrate of the content stream 203. The first bit rate is higher than thesecond bit rate which is higher than the nth bit rate.

Referring to FIG. 6, there is a diagram of an exemplary system 600including the streaming server 206 (e.g., adaptive streaming server 206)configured to receive a live content stream 203 and then adaptivelydeliver the live content stream 203 via an IP network 208 to one or moreclients 202 in accordance with an embodiment of the present invention.The adaptive streaming server 206 is configured to create the livecontent stream 203 to be delivered to one or more clients 202 bysegmenting the live content stream 203 into data structures which arestored in random access memory 211 (volatile storage 211) rather thansegmenting the live content stream 203 into segment files which arestored on a disk or within a database (non-volatile storage). In thisexample, the adaptive streaming server 206 includes a multicast packetescrow 610, a configurable length non-volatile memory packet escrow 612(which stores the content stream 203), the segmenting unit 210, theserver 212, and the random access memory 211. The exemplary system 600which enables adaptive streaming in a broadcast start-over-time shiftedtelevision (TSTV) environment includes the following components:

-   -   Adaptive Streaming Clients 202: personal computers, mobile        phones/tablets, http capable televisions, etc.    -   Adaptive Streaming Friendly Encoder/Trans-coder 602—Ensures that        any content stream 203 which the adaptive streaming server 206        receives as input will be in a manageable format.    -   Adaptive Streaming Server 206—Handles segmenting the content        stream 203 into data structures and producing streams for the        adaptive streaming clients 202 (see FIGS. 2 and 3). Although, an        adaptive streaming server 206 is described herein it should be        appreciated that the present invention also includes a streaming        server that works on a stream that has only a single bit rate.    -   CDN or Content Store 604—Content Distribution Network or Storage        system where content streams 203 can be warehoused after being        received from different ingestions inlets.

The exemplary system 600 may include many other well known componentsbut for clarity those well known components are not described hereinwhile the components 202, 206, 602, 604, 606 which are relevant to thepresent invention have been described herein. The exemplary system 600is configured to provide a finished live adaptive content stream 203 toone or more requesting clients 202 (only three shown) per the followingsteps:

-   -   1. The adaptive streaming clients 202 have access to a channel        line-up and guide data listings 608 to find out what programs        (content streams 203) are currently available.    -   2. The adaptive streaming clients 202 locate a program (content        stream 203) to watch and a request to play the broadcast live or        TSTV program (content stream 203) is made to the adaptive        streaming server 206. It should be noted a VOD stream has a        beginning and an end while a broadcast stream has a beginning        and then grows with time.    -   3. The adaptive streaming server 206 also has access to the        channel lineup and guide data listing 608. The adaptive        streaming server 206 uses this information to locate the        requested content stream 203.    -   4. In this case, the requested key frame aligned content stream        203 is arriving off the broadcast feed in a multi-program        transport stream format from the broadcast network 606.        Alternatively, the CDN 604 could contain the requested content        stream 203    -   5. The adaptive streaming friendly encoder/trans-coder 602        reformats the content stream 203 from the broadcast network 606        as required and provides the reformatted content stream 203 as        input to the adaptive streaming server 206. The adapted        streaming server 206 upon receiving the properly formatted        content stream 203 segments the content stream 203 to create a        set of data structures which are stored in the random access        memory. If the content stream 203 is in a multi-program        transport stream format then the adaptive streaming server 206        will demultiplex each content stream (with same content but        different bit rates) into their own set of data structures in        single-program transport stream formats.    -   6. The adaptive streaming server 206 sends the master manifest        which references fragments of the content stream 203 to the        clients 202. The master manifest can be unique per client 202        and is a set of references to fragments of the content stream        203 that the adaptive streaming server 206 can create on demand.    -   7. The content stream 203 itself is delivered to the client as a        set of segmented files however the data structures referenced by        the master manifest were used to accomplish this. In other        words, no static segment files from a disk or database        (non-volatile storage) in the traditional way were required in        order to deliver the content stream 203.

Referring to FIG. 7, there is a diagram of an exemplary system 700including the streaming server 206 (e.g., adaptive streaming server 206)configured to receive a on-demand content stream 203 and then adaptivelydeliver the on-demand content stream 203 via an IP network 208 to one ormore clients 202 in accordance with an another embodiment of the presentinvention. The adaptive streaming server 206 is configured to create theon-demand content stream 203 to be delivered to one or more clients 203by segmenting the on-demand content stream 203 into data structureswhich are stored in random access memory 211 (volatile storage 211)rather than segmenting the on-demand content stream 203 into segmentfiles which are stored on a disk or within a database (non-volatilestorage). In this example, the adaptive streaming server 206 includesthe segmenting unit 210, the server 212, and the random access memory211. The exemplary system 700 which enables adaptive streaming in avideo-on-demand environment includes the following components:

-   -   Adaptive Streaming Clients 202: personal computers, mobile        phones/tablets, http capable televisions, etc.    -   Adaptive Streaming Server 206—Handles segmenting the content        stream 203 into data structures and producing streams for the        adaptive streaming clients 202 (see FIGS. 2 and 3). Although, an        adaptive streaming server 206 is described herein it should be        appreciated that the present invention also includes a streaming        server that works on a stream that has only a single bit rate.    -   CDN or Content Store 604—Content Distribution Network or Storage        system where content streams 203 can be warehoused after being        received from different ingestions inlets.    -   VOD Content 203—Multiple key frame aligned video/audio streams        203. It should be noted a VOD stream has a beginning and an end        while a broadcast stream has a beginning and then grows with        time.

The exemplary system 700 may include many other well known componentsbut for clarity those well known components are not described hereinwhile the components 202, 206, 602, and 604 which are relevant to thepresent invention have been described herein. The exemplary system 700is configured to provide a finished on-demand adaptive content stream203 to one or more requesting clients 202 (only three shown) per thefollowing steps:

-   -   1. The adaptive streaming clients 202 makes a request to the        adaptive streaming server 206 for play of a VOD asset (on-demand        content stream 203).    -   2. The adaptive streaming server 206 retrieves the requested key        framed aligned VOD content stream 203 from the CDN 604 and        segments the retrieved content stream 203 creating a set of data        structures to send to the clients 202.    -   3. The adaptive streaming server 206 sends the manifest which        references fragments of the content stream 203 to the clients        202. The manifest can be unique per client 202 and is a set of        pointers to locations in the content stream 203 that the        adaptive streaming server 206 is now creating.    -   4. The content stream 203 itself is delivered to the client as a        set of segmented files however the data structures referenced by        the manifest were used to accomplish this. In other words, no        static segment files from a disk or database (non-volatile        storage) in the traditional way were required in order to        deliver the content stream 203.

In view of the foregoing, one should appreciate that the adaptivestreaming server 206 which is configured to deliver an adaptive contentstream 203 from managed data structures rather than static files hasmany advantages (for example).

-   -   The content streams 203 can now be made available to clients 202        before their segmentation is completed by the segmenting unit        210. This provides faster service delivery to clients 203 when        dealing with live content streams 203.    -   The adaptive streaming server 206 on the fly can change segment        boundaries and extract subsets of the content stream 203 for the        client 202 without having to create new files. Being able to        redefine segment boundaries greatly enhances how the adaptive        streaming server 206 can manage its content. It also makes it        easier for the adaptive streaming server 206 to insert        advertisement or alternative stream into the content stream 203.    -   Stream segmentation happens only when it becomes necessary to        play the content stream 203. This is a huge savings in space        consumption on the adaptive streaming server 206.    -   The traditional adaptive streaming server had limited        flexibility in dividing (chopping up) a segment file which made        extracting a subset of a segment rather difficult. The adaptive        streaming server 206 addresses this problem by including logic        which can segment the file at any boundary on-demand. This logic        is used for every segment and is not a special case.    -   The traditional adaptive server requires redundant copies of VOD        streams as the server tries to store the original content file        and all of its additional segment files. The adaptive streaming        server 206 addresses this problem by computing the segments        on-demand instead of storing the segments in files.

Although multiple embodiments of the present invention have beenillustrated in the accompanying Drawings and described in the foregoingDetailed Description, it should be understood that the invention is notlimited to the disclosed embodiments, but instead is also capable ofnumerous rearrangements, modifications and substitutions withoutdeparting from the present invention that as has been set forth anddefined within the following claims.

1. A streaming server comprising: a processing unit; a random accessmemory unit coupled to the processing unit; and wherein the streamingserver is configured to receive a request to play a content stream,receive the content stream, segment the content stream into a pluralityof data structures, and store the plurality of data structures in therandom access memory unit.
 2. The streaming server of claim 1, whereinthe streaming server is configured to segment the content stream intothe plurality of data structures rather than into a plurality of segmentfiles.
 3. The streaming server of claim 1, wherein the plurality of datastructures encompass (1) a reference to the content stream and (2)pointers which correspond to time codes to the content stream.
 4. Thestreaming server of claim 1, where the streaming server is configured tosegment the content stream into the plurality of data structures onlywhen it becomes necessary to output one or more fragments of the contentstream.
 5. The streaming server of claim 1, wherein the content streamis one of a single program transport stream, a multi-program transportstream, a video-on-demand content stream, or a live content stream.
 6. Amethod in a streaming server, the method comprising: receiving a requestto play a content stream; receiving the content stream; segmenting thecontent stream into a plurality of data structures; and storing theplurality of data structures in a random access memory unit.
 7. Themethod of claim 6, wherein the content stream is segmented into theplurality of data structures rather than into a plurality of segmentfiles.
 8. The method of claim 6, wherein the plurality of datastructures encompass (1) a reference to the content stream and (2)pointers which correspond to time codes to the content stream.
 9. Themethod of claim 6, where the content stream is segmented into theplurality of data structures only when it becomes necessary to outputone or more fragments of the content stream.
 10. The method of claim 6,wherein the content stream is one of a single program transport stream,a multi-program transport stream, a video-on-demand content stream, or alive content stream.
 11. A streaming server for providing a contentstream through a network to a client, the streaming server comprising: aHypertext Transfer Protocol (HTTP) server comprising an input interfaceat which there is received a request from the client to play the contentstream; a segmenting unit configured to receive the content stream andsegment the content stream into a plurality of data structures, whereinthe plurality of data structures encompass (1) a reference to thecontent stream and (2) pointers which correspond to time codes to thecontent stream; a random access memory unit configured to store theplurality of data structures; the HTTP server further comprising: aprocessing unit configured to generate a manifest that includes aplurality references corresponding to a plurality of fragments of thecontent stream; an output interface from which the manifest is sent tothe client; the input interface at which there is received a requestfrom the client to fetch one of the fragments corresponding to thecontent stream; the processing unit configured to obtain bytesassociated with the requested fragment from the data structures storedin the random access memory unit, wherein the processing unit uses timecodes associated with the requested fragment to lookup bytes from one ormore of the data structures associated with the requested fragment; andthe output interface from which there is sent the bytes associated withthe requested fragment to the client.
 12. The streaming server of claim11, wherein the content stream is segmented into the plurality of datastructures rather than into a plurality of segment files.
 13. Thestreaming server of claim 11, where the processing unit is configured toperform an interpolation process when looking-up the bytes from the oneor more data structures associated with the requested fragment.
 14. Thestreaming server of claim 11, where the HTTP server is configured tosend the manifest to the client before the segmenting unit completessegmenting the content stream into the plurality of data structures. 15.The streaming server of claim 11, where the segmenting unit isconfigured to segment the content stream into the plurality of datastructures only when it becomes necessary to provide one or more of thefragments of the content stream to the client.
 16. The streaming serverof claim 11, wherein: the client is an adaptive streaming capableclient; and the content stream is one of a single program transportstream, a multi-program transport stream, a video-on-demand contentstream or a live content stream.
 17. A method in a streaming server forproviding a content stream through a network to a client, the methodcomprising: receiving a request from the client to play the contentstream; receiving the content stream; segmenting the content stream intoa plurality of data structures, wherein the plurality of data structuresencompass (1) a reference to the content stream and (2) pointers whichcorrespond to time codes to the content stream; storing the plurality ofdata structures in a random access memory unit; generating a manifestthat includes a plurality references corresponding to a plurality offragments of the content stream; sending the manifest to the client;receiving a request from the client to fetch one of the fragmentscorresponding to the content stream; obtaining bytes associated with therequested fragment from the data structures stored in the random accessmemory unit by using time codes associated with the requested fragmentto lookup bytes from one or more of the data structures associated withthe requested fragment; and sending the bytes associated with therequested fragment to the client.
 18. The method of claim 17, whereinthe content stream is segmented into the plurality of data structuresrather than into a plurality of segment files.
 19. The method of claim17, wherein the obtaining operation further comprises an interpolationprocess when looking-up the bytes from the one or more data structuresassociated with the requested fragment.
 20. The method of claim 17,wherein the manifest is sent to the client before completing thesegmenting the content stream into the plurality of data structures. 21.The method of claim 17, wherein the segment operation is performed onlywhen it becomes necessary to provide one or more of the fragments of thecontent stream to the client.
 22. The method of claim 17, wherein: theclient is an adaptive streaming capable client; and the content streamis one of a single program transport stream, a multi-program transportstream, a video-on-demand content stream or a live content stream.